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Three-dimensional Imaging Method of Line Array SAR Based on Threshold Gradient Pursuit Algorithm

A tracking algorithm, linear array technology, applied in radio wave measurement systems, radio wave reflection/re-radiation, instruments, etc., can solve problems such as limited application, increased cost, and large amount of echo data.

Active Publication Date: 2020-06-16
UNIV OF ELECTRONICS SCI & TECH OF CHINA
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AI Technical Summary

Problems solved by technology

Under the premise of the traditional imaging system and data processing method, in order to achieve high-resolution earth observation, the linear array 3D SAR imaging technology faces the following challenges: (1) The load conditions are limited: for the ka-band airborne platform, at a height of 3km, it is necessary to To realize observation with a resolution of 0.05m, the length of the linear array is required to be more than 300m, which is difficult to meet with the size of the existing airborne platform; (2) too many elements of the linear array: in order to suppress side lobes and grating lobes, it is usually necessary to use full sampling Line array antennas need to use thousands of array elements at least, and tens of thousands of array elements at most. The hardware system is complex and costly
(3) Insufficient imaging precision: At present, the back projection (BP) algorithm is mainly used for linear array 3D SAR data processing. The side lobe of the scattering target is covered, and the resolution of the cut track is often much lower than the other two dimensions due to the limitation of the length of the linear array, which restricts the application of the linear array 3D SAR; (4) The amount of echo data is too large: all array elements of the linear array 3D SAR are in the Echoes are collected within each pulse repetition time, and the amount of echo data is often thousands of times that of traditional SAR, making data sampling, storage, transmission, and processing more difficult and costly
As a common greedy algorithm, the OMP algorithm also has important applications in SAR 3D imaging, but for large-scale problems, the OMP algorithm is relatively inefficient in terms of running time and space storage
Thomas Blumensath et al. proposed the GP algorithm, which is more efficient than the OMP algorithm in terms of running time and space storage. However, like the OMP algorithm, the GP algorithm also needs to preset the sparseness of the scene, which is generally not available in SAR 3D imaging. The true sparsity of the scene
thus limiting their application

Method used

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  • Three-dimensional Imaging Method of Line Array SAR Based on Threshold Gradient Pursuit Algorithm
  • Three-dimensional Imaging Method of Line Array SAR Based on Threshold Gradient Pursuit Algorithm
  • Three-dimensional Imaging Method of Line Array SAR Based on Threshold Gradient Pursuit Algorithm

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Embodiment Construction

[0085] The present invention mainly adopts the method of simulation experiment to verify, and all steps and conclusions are verified on MATLABR2008b. The specific implementation steps are as follows:

[0086] Step 1. Initialize the linear array SAR system parameters required for simulation:

[0087] Initialize the values ​​of the linear array SAR system parameters such as image 3 shown, including: motion platform velocity vector The total number of array elements of the linear array antenna N=201, the initial position vector of each array element of the linear array antenna Where n is the array element number of the nth linear array antenna, n=1,2,...,N, N=201, the length of the linear array antenna is L=3m, and the distance between adjacent array elements of the linear array antenna is d= 0.015m, radar center frequency f c =10GHz, the signal width B of the baseband signal of the radar transmitter r =300MHz, radar transmit signal pulse width T P =10 -6 s, frequency m...

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Abstract

The invention provides a linear array SAR three-dimensional imaging method based on a threshold gradient tracking algorithm, which uses the linear array SAR radar system parameters, motion platform parameters, and the relationship between the spatial parameters of the observed scene target and the original echo signal to establish a linear array The linear measurement model between the SAR original echo signal and the scattering coefficient of the target in the 3D observation scene, and then based on the linear measurement model of the signal, the TBGP method is used to complete the reconstruction of the scattering coefficient of the target in the observation scene, and the maximum and minimum values ​​of the target are used in each iteration process Scattering coefficient contrast and target scattering coefficient change rate are used as the termination condition of the algorithm iteration, which improves the linear array SAR sparse imaging performance of the GP algorithm under the condition of unknown sparseness of the observation scene. Compared with the OMP algorithm, the calculation efficiency and space storage efficiency are improved, and it can be applied to the synthesis Aperture radar imaging and earth remote sensing and other fields.

Description

technical field [0001] The invention belongs to the technical field of radar, in particular to the technical field of synthetic aperture radar (SAR) imaging. Background technique [0002] Traditional Synthetic Aperture Radar (SAR) uses the linear motion of a single antenna to synthesize a one-dimensional virtual linear array antenna to obtain high resolution in the azimuth direction, and then uses pulse compression technology to obtain high resolution in the radar line of sight direction, thereby realizing two-dimensional imaging of the observation scene . However, the traditional 2D SAR mainly works in the side-view imaging mode, and there are terrain occlusion, shadow effects and top-bottom inversion problems in the side-view imaging, so the traditional 2D SAR cannot obtain satisfactory results in complex undulating terrain such as cities, mountains and canyons. Imaging results. The basic principle of 3D SAR is to synthesize a virtual two-dimensional area array antenna t...

Claims

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Application Information

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Patent Type & Authority Patents(China)
IPC IPC(8): G01S13/90
CPCG01S13/90G01S13/9004G01S13/904
Inventor 张晓玲周黎明左林电韦顺军田博坤
Owner UNIV OF ELECTRONICS SCI & TECH OF CHINA
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